ALBERT

Description: We investigate a large geodetic data set of interferometric synthetic aperture radar (InSAR) and GPS measurements to determine the source parameters for the three main shocks of the 2016 Central Italy earthquake sequence on 24 August and 26 and 30 October (M w 6.1, 5.9, and 6.5, respectively). Our preferred model is consistent with the activation of four main coseismic asperities belonging to the SW dipping normal fault system associated with the Mount Gorzano-Mount Vettore-Mount Bove alignment. Additional slip, equivalent to a M w  ~ 6.1–6.2 earthquake, on a secondary (1) NE dipping antithetic fault and/or (2) on a WNW dipping low-angle fault in the hanging wall of the main system is required to better reproduce the complex deformation pattern associated with the greatest seismic event (the M w  6.5 earthquake). The recognition of ancillary faults involved in the sequence suggests a complex interaction in the activated crustal volume between the main normal faults and the secondary structures and a partitioning of strain release. ©2017. The Authors.

Description: A combined GPS velocity solution covering a wide area from Egypt to Middle East allowed us to infer the current rates across the main, already well known, tectonic features. We have estimated 126 velocities from time series of 90 permanent and 36 non permanent GPS sites located in Africa (Egypt), Eurasia and Arabia plates in the time span 1996–2015, the largest available for the Egyptian sites. We have combined our velocity solution in a least-squares sense with two other recent velocity solutions of networks located around the eastern Mediterranean, obtaining a final IGb08 velocity field of about 450 sites. Then, we have estimated the IGb08 Euler poles of Africa, Sinai and Arabia, analyzing the kinematics of the Sinai area, particular velocity profiles, and estimating the 2D strain rate field. We show that it is possible to reliably model the rigid motion of Sinai block only including some GPS sites located south of the Carmel Fault. The estimated relative motion with respect to Africa is of the order of 2–3 mm/yr, however there is a clear mismatch between the modeled and the observed velocities in the southern Sinai sites. We have also assessed the NNE left shear motion along the Dead Sea Transform Fault, estimating a relative motion between Arabia and Africa of about 6 mm/yr in the direction of the Red Sea opening.

Description: Published

Description: 231-238

Description: 2T. Tettonica attiva

Description: JCR Journal

Description: restricted

Description: We probe the feasibility of integrating GPS and Synthetic Aperture Radar deformation rates within the seismic hazard models of the central Apennines (Italy), exploiting data from over 100 GPS stations and the ~20- year long ERS and ENVISAT SAR image archive. We then use a kinematic finite element model to derive the long-term strain rates, as well as earthquake recurrence relations. In turn these are input to state-of-the-art probabilistic seismic hazard models, the output of which is validated statistically using data from the Italian national accelerometric and macroseismic intensity databases.

Description: Published

Description: 23-27

Description: 3T. Pericolosità sismica e contributo alla definizione del rischio

Description: N/A or not JCR

Description: restricted

Description: The GPS results are of utmost relevance for the study of the complex plate boundary geodynamics. The lithosphere strain partitioning is part of the seismic cycle. We present the first GPS kinematic pattern obtained during the interseismic phase by a dense episodic GPS network, the Southern Apennine Geodetic Network - SAGNet (Sepe et al., 2009), in the time span 2002-2013. This network is located across the transition zone between central and southern Apennine, including Meta-Mainarde-Venafro and AltoMolise-Sannio-Matese mounts. This region is characterized by seismogenic fault systems responsible, in the past, for several destructive earthquakes of intensity I ≥ IX MCS and, in more recent years, characterised mainly by some moderate magnitude seismic sequences (max magnitude Mw 5.0, December 29 2013) and single small events (Ml 〈 2.5).SAGNet GPS data were processed by BERNESE sw v.5.0 and the resulting velocities were least-squares combined with the permanent stations velocity field and with the velocity solution of Giuliani et al. 2009. The combined GPS velocity field, shows a perpendicular maximum extension with respect to the Apennine chain of about 2.0 mm/y.The Matese area was hit on December 29, 2013 by a Mw=5.0 (Convertito et al., 2016) earthquake. It was followed by an intense seismic activity until the beginning of February 2014. After the mainshock a GPS survey was carried out on the SAGnet stations. We collected data from 2013, 30 December to 2014, 4 April. The time series of 17 stations are affect by an offsets on the linear drift. The map of horizontal coseismic displacements (Figure 3) shows a sub-radial displacement shape with respect to the epicentre. Larger displacements are observed in correspondence of NE portion of the Matese massif. Considering the Matese Lake Fault as the probable source of the mainshock (dip 65°, strike 116, rake 270 – MLF, Ferranti et al, 2015), we found that the Okada modelling does not fit the observed displacements and only a small fraction of displacements are resolved with a simple slip.Figure 4 resembles the results of previous studies compared with our GPS analysis. We considered seismological analyses, tomographic models, degassing of CO2 data and conceptual model of processes recognized in South Apennine (L. Bisio, et al., 2004; Chiarabba and Chiodini, 2013; Improta et al., 2014; Ventura et al., 2007, R. Di Stefano and M.G. Ciaccio, 2014; Ferranti et al., 2015; Convertito et al., 2016;). The GPS results indicate that the relative motion between Eurasia and Adria plates is responsible of the active deformation in the Apennines. The most important outcomes of this study are: (i) During the interseismic phase the differential motion between Adriatic and Tyrrhenian domains seems to be accommodated in a narrow belt bordering the westward flank of the Sannio Mts, showing a 2 mm/y extension. (ii) The maximum extension does not follow the topographic high of the chain but is shifted toward the eastern outer belt. (iii) No significant GPS deformation is highlighted in correspondence of major and known fault systems where the GPS velocities appear almost steady. We propose that the observed coseismic displacements are only marginally explained by a slip on the MLF fault. The vertical directivity and depth distribution of the seismic sequence (Convertito et al., 2016), the vertical and horizontal heterogeneity of lower crust and upper mantle (Bisio et al., 2004; Di Stefano and Ciaccio, 2014), the high flux of CO2 degassing (Ventura et al., 2007, Chiarabba e Chiodini, 2013 ), the probable presence of pressurized CO2 bodies fed by fluids uprising from the mantle wedge (Improta et al.,2014 ), suggest instead that the seismic sequence could be caused by sub-vertical cracks that originate at the Moho interface and reach the bottom of the seismogenic layer (10km depth).

Description: DPC

Description: Unpublished

Description: San Francisco (USA)

Description: 2T. Tettonica attiva

Description: open

Description: A brief historical overview of the Italian geophysical studies using satellite positioning observations.

Description: Published

Description: 33–41

Description: 2T. Tettonica attiva

Description: 1IT. Reti di monitoraggio e Osservazioni

Description: N/A or not JCR

Description: reserved

Description: Several thousands GPS/GNSS permanent stations, managed by both scientifc and cadastral institutions, are now available on the European plate and its boundaries. Data coming from these stations provide unprecedented spatial and temporal coverage of time-dependent deformation signals essential to understand the fundamental physics that govern tectonic deformation and faulting. The National Earthquake Center (Centro Nazionale Terremoti, CNT) of the National Institute of Geophysics and Volcanology (Istituto Nazionale di Geofisica e Vulcanologia, INGV) in Italy, is the Italian leader institution for the collection, management and scientific analysis of Global Positioning Systems (GPS) measurements. Distinct analysis centers independently and routinely process and analyze data using high-quality geodetic software (Bernese, Gamit, Gipsy) to measure the movements of 〉1000 points spanning the Eurasian plate and its boundaries. The goal of this project is to offer high-quality geodetic products, increase their accessibility to the European scientific community and promote the inter-disciplinary data exchange through a multi-level, user-friendly data gateway. These activities will be performed in strict contact with the GNSS Working Group of the EPOS project (http://www.eposeu.org) that is proposing to integrate, archive and distribute data, metadata and products for available GNSS stations on the European plate.

Description: Published

Description: Vienna, Austria

Description: 2T. Tettonica attiva

Description: open

Description: The contribution of space geodetic techniques to interseismic velocity estimation, and thus seismic hazard modelling, has been recognized since two decades and made possible in more recent years by the increased availability and accuracy of geodetic measurements. We present the preliminary results of a feasibility study performed within the CHARMING project (Constraining Seismic Hazard Models with InSAR and GPS), funded by the European Space Agency (ESA). For a 200 km x 200 km study area, covering the Abruzzi region (central Italy) we measure the mean surface deformation rates from Synthetic Aperture Radar and GPS, finding several local to regional deformation gradients consistent with the tectonic context. We then use a kinematic finite element model to derive the long-term strain rates, as well as earthquake recurrence relations. In turn these are input to state-of-the-art probabilistic seismic hazard models, the output of which is validated statistically using data from the Italian national accelerometric and macroseismic intensity databases.

Description: Published

Description: 373-377

Description: 3T. Pericolosità sismica e contributo alla definizione del rischio

Description: N/A or not JCR

Description: open

Description: Since the early 1970s, geodetic networks became a most important tool to monitor the present day deformations of the volcanic arc of the Aeolian Islands. The first benchmarks were installed in this region at Lipari and Vulcano Islands and the number of GPS benchmarks increased in time since the early ’90s. These networks were periodically surveyed in the frame of national and international geodynamic projects and for Civil Protection programs devoted to the mitigation of the volcanic hazard. The Istituto Nazionale di Geofisica e Vulcanologia (INGV) played a fundamental role in the realization and periodical reoccupation of these networks, with the goal to investigate the tectonic and volcanic processes, still active in this crucial area of the central Mediterranean. An updated GPS velocity map for this region, both for the horizontal and vertical component of land motion, with details for Lipari, Vulcano and Panarea Islands, is provided in this paper. The presented GPS velocity field also includes a set of additional discrete stations located in northern Sicily and Calabria together with data from the available CGPS networks active in southern Italy. Here we show the results from eighteen years of repeated GPS surveys performed in this region in the time span 1995-2013 and the open access AINET-GPS data archive, now freely available for the scientific community. Data will support scientific research and hopefully improve the assessment of volcanic and seismic hazard in this region

Description: Published

Description: S0439

Description: 1V. Storia e struttura dei sistemi vulcanici

Description: JCR Journal

Description: restricted